Friday, July 20, 2018

Three years ago, the drought-stricken city of Los Angeles covered the surface of the LA Basin with 96 million shade-providing floating balls, in order to keep the water beneath from evaporating. Now, an international study suggests that the making of the plastic balls may have have used up more water than they saved.

The "shade balls" were left in place on the reservoir for approximately one and a half years, during the latter part of the 2011 - 2017 California drought. According to the study, they kept an estimated 1.7 million cubic meters (60 million cubic feet) of water from evaporating. Unfortunately, however, it is also estimated that production of the balls used up 2.9 million cubic meters of water (102 million cubic feet). This happened at locations where the oil and natural gas used to produce the plastic were refined, and where the electricity necessary for production was generated.

In order for the shade balls to save as much water as was used in manufacturing them, they would reportedly have to be left on the reservoir for at least two and a half years – and that's only if drought conditions persisted for the entire period.

Additionally, the study points out that the manufacturing process would have had other negative environmental costs, such as the generation of carbon emissions and water pollution.

"We are very good at quick technological fixes, but we often overlook the long-term and secondary impacts of our solutions," says study co-author Dr. Kaveh Madani, from Imperial College London. "This is how the engineering community has been solving problems; solving one problem somewhere and creating a new problem elsewhere … We are not suggesting that shade balls are bad and must not be used. We are just highlighting the fact that the environmental cost of shade balls must be considered together with their benefits."

The findings of the study, which also included scientists from MIT in the US and the University of Twente in the Netherlands, were recently published in the journal Nature Sustainability.

Friday, July 13, 2018

Date: July 12, 2018Source: Washington State UniversitySummary: Researchers have created a sustainable alternative to traditional concrete using coal fly ash, a waste product of coal-based electricity generation.

Chemical engineering student Ka Fung Wong looks at the data log, which is used to gather data from sensors buried under the concrete test plot.Credit: WSU

Washington State University researchers have created a sustainable alternative to traditional concrete using coal fly ash, a waste product of coal-based electricity generation.

The advance tackles two major environmental problems at once by making use of coal production waste and by significantly reducing the environmental impact of concrete production.

Xianming Shi, associate professor in WSU's Department of Civil and Environmental Engineering, and graduate student Gang Xu, have developed a strong, durable concrete that uses fly ash as a binder and eliminates the use of environmentally intensive cement. They report on their work in the August issue of the journal, Fuel.

Reduces Energy Demand, Greenhouse Emissions

Production of traditional concrete, which is made by combining cement with sand and gravel, contributes between five and eight percent of greenhouse gas emissions worldwide. That's because cement, the key ingredient in concrete, requires high temperatures and a tremendous amount of energy to produce.

Fly ash, the material that remains after coal dust is burned, meanwhile has become a significant waste management issue in the United States. More than 50 percent of fly ash ends up in landfills, where it can easily leach into the nearby environment.

While some researchers have used fly ash in concrete, they haven't been able to eliminate the intense heating methods that are traditionally needed to make a strong material.

"Our production method does not require heating or the use of any cement," said Xu.

Molecular Engineering

This work is also significant because the researchers are using nano-sized materials to engineer concrete at the molecular level.

"To sustainably advance the construction industry, we need to utilize the 'bottom-up' capability of nanomaterials," said Shi.

The team used graphene oxide, a recently discovered nanomaterial, to manipulate the reaction of fly ash with water and turn the activated fly ash into a strong cement-like material. The graphene oxide rearranges atoms and molecules in a solution of fly ash and chemical activators like sodium silicate and calcium oxide. The process creates a calcium-aluminate-silicate-hydrate molecule chain with strongly bonded atoms that form an inorganic polymer network more durable than (hydrated) cement.

Aids Groundwater, Mitigates Flooding

The team designed the fly ash concrete to be pervious, which means water can pass through it to replenish groundwater and to mitigate flooding potential.

Researchers have demonstrated the strength and behavior of the material in test plots on the WSU campus under a variety of load and temperature conditions. They are still conducting infiltration tests and gathering data using sensors buried under the concrete. They eventually hope to commercialize the patented technology.

"After further testing, we would like to build some structures with this concrete to serve as a proof of concept," said Xu.

The research was funded by the U.S. Department of Transportation's University Transportation Centers and the WSU Office of Commercialization.

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The American Academy of Environmental Engineering and Scientists is a not-for-profit 501(c)(6) organization serving the Environmental Engineering and Environmental Science professions by providing Board Certification to those who qualify through experience and testing. The Academy also provides training through workshops and seminars, participates in accrediting universities, publishes a periodical and other reference material, interacts with students and young professionals, sponsors a university lecture series, and rewards outstanding achievements through its international awards program.